谷胱甘肽
铬
代谢组学
新陈代谢
代谢途径
生物
转录组
查尔酮合酶
脂质代谢
化学
植物螯合素
抗氧化剂
生物技术
超量积累植物
转录因子
戒毒(替代医学)
氧化磷酸化
次生代谢
硫代谢
植物修复
氧化应激
类胡萝卜素
作物生产力
植物代谢
GCLC公司
生物化学
作者
Yuanpeng Fang,Zehui Wang,Nisar Uddin,A. K. Srivastava,Sanwei Yang,Xin Xie
标识
DOI:10.1021/acs.est.5c04872
摘要
Chromium (Cr) contamination affects over 20 million hectares globally, threatening agricultural productivity and food safety. Current phytoremediation efforts face challenges due to a limited understanding of Cr-tolerance mechanisms and the unclear role of anthocyanins in metal detoxification. This study investigates Cr-tolerance responses in two Brassica rapa varieties: the tolerant chinensis (BRC) and the sensitive purpuraria (BRP), using an integrated multiomics framework. BRC showed 30% less biomass reduction than BRP under Cr stress. Genomic analysis identified gene clusters specific to BRC associated with metabolic flexibility. Transcriptomic and metabolomic profiling revealed regulatory networks driven by transcription factors that support tolerance. Mechanisms contributing to Cr-tolerance included improved root glutathione metabolism for Cr sequestration, suppressed glyoxylate pathways in the stem to reduce oxidative stress, and increased leaf cysteine and methionine metabolism to support antioxidant production. Notably, anthocyanin accumulation did not correlate with Cr-tolerance; BRP accumulated 15% more anthocyanins than BRC under stress. The findings indicate that Cr-tolerance in B. rapa relies on metabolic changes and transcriptional control of detoxification pathways, not anthocyanins. Identifying key targets in specific tissues, such as root glutathione synthase and leaf sulfur metabolism pathways, offers potential avenues for developing Cr-resistant crop varieties and enhancing agricultural sustainability in metal-contaminated soils.
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